Expression of Biologically Active Crustacean Hyperglycemic Hormone (CHH) of <Emphasis Type="Italic">Penaeus monodon</Emphasis> in <Emphasis Type="Italic">Pichia pastoris</Emphasis>

Crustacean hyperglycemic hormone (CHH), molt-inhibiting hormone (MIH), and gonad-inhibiting hormone (GIH) are members of a major peptide family produced from the X-organ sinus gland complex in the eyestalk of crustaceans. This peptide family plays important roles in controlling several physiologic processes such as regulation of growth and reproduction. In this study the complementary DNA encoding a peptide related to the CHH/MIH/GIH family (so-called Pem-CMG) of the black tiger prawn Penaeus monodon was successfully expressed in the yeast Pichia pastoris under the control of the AOX1 promoter. The recombinant Pem-CMG was secreted into the culture medium using the -factor signal sequence; of Saccharomyces cerevisiae without the Glu-Ala-Glu-Ala spacer peptide. The amino terminus of the recombinant Pem-CMG was correctly processed as evidenced by amino-terminal peptide sequencing. The recombinant Pem-CMG was purified by reverse-phase high-performance liquid chromotography and used in a biological assay for CHH activity. The final yield of the recombinant Pem-CMG after purification was 260 µg/L of the culture medium. Both crude and purified recombinant Pem-CMG produced from P. pastoris showed the ability to elevate the glucose level in the hemolymph of eyestalk-ablated P. monodon, which demonstrates that Pem-CMG peptide functions as hyperglycemic hormone in P. monodon.     

The crustacean hyperglycemic hormone precursors a and b of the Norway lobster differ in the preprohormone but not in the mature peptide

The neuro-endocrine X-organ sinus-gland complex of crustaceans produces and releases the neuropeptides of the crustacean hyperglycemic hormone (cHH)/molt-inhibiting hormone (MIH)/gonad-inhibiting hormone (GIH) family that regulate important physiological processes, such as growth, reproduction and molting. We cloned two full-length cDNAs encoding the preprocHH-A and preprocHH-B of the Norway lobster Nephrops norvegicus of 132 and 131 amino acid residues. The two cHHs differ in the preprohormone but not in the mature peptide sequence. The mature cHH was expressed in bacteria as GST fusion protein that, in bioassay, shows a hyperglycemic activity similar to that of native cHH present in an eyestalk extract.     

Structure-activity relationships on hyperglycemia by representatives of the adipokinetic/hyperglycemic hormone family in Blaberus discoidalis cockroaches

Summary Several members of the adipokinetic/hyperglycemic neurohormone family from several different invertebrate species have been prepared by solid-phase peptide synthesis and assayed by a modified in vivo hyperglycemic bioassay in Blaberus discoidalis cockroaches. The hypertrehalosemic hormone (HrTH) is the endogenous hypertrehalosemic factor for B. discoidalis and was the most potent peptide in the assay. The more divergent the sequence of a family member from Blaberus HrTH, the less potent was the bioanalog. Manduca adipokinetic hormone is the most divergent peptide of the family and was totally inactive in the bioassay. Locusta adipokinetic hormone I had reduced maximum activity in the assay, which suggests that Ser⁵ is an important residue for the transduction of the hyperglycemic response. The direct relation between bioanalog similarity to Blaberus HrTH sequence and potency suggests that the hormone and target cell receptor for HrTH have evolved to maintain an optimal fit.Abbreviations AKH adipokinetic hormone - HrGH hyperglycemic hormone - HrTH hypertrehalosemic hormone - RPCH red pigmentconcentrating hormone - CAH cardioacceleratory hormone. Hormone abbreviations are according to the convention of Gäde and Raina (1989) except that the genus names are not abbreviated     

Biochemical and functional aspects of crustacean hyperglycemic hormone in decapod crustaceans: review and update

In crustaceans, neuroendocrine centers are located in different structures of the nervous system. One of these structures, the X-organ-sinus gland complex of the eyestalk, produces several neuropeptides that belong to the two main functionally different families: firstly, the chromatophorotropins, and secondly, a large family comprising various closely related peptides, commonly named CHH/MIH/GIH family. This review updates some aspects of the structural, biochemical and functional properties of the main hyperglycemic neuropeptide of this family, the crustacean hyperglycemic hormone (CHH). The first part of this work is a survey of the neuroendocrine system that produces the neurohormones of the CHH/MIH/GIH family, focusing on recent reports that propose new possible neuroendocrine loci of CHH production, secondly we revise general aspects of the CHH biochemical, and structural characteristics and thirdly, we present a review of the role of CHH in the regulation of several physiological processes of crustaceans as well as new reports on the ontogenetic aspects of CHH. The review is centered only on one group of malacostracan crustaceans, the Decapoda.     

miR‐34 regulates reproduction by inhibiting the expression of MIH,CHH, EcR,and FAMeT genes in mud crab Scylla paramamosain

Mud crab Scylla paramamosain is a commercially important species widely cultured in China. It is well known that the eyestalk regulates reproductive activities in crustaceans. In our previous research, we found that the miR‐34 expression level in male eyestalk was significantly higher than that in females. Thus, we assumed that it may play an important role in regulating reproduction. In this study, we used bioinformatic tools to identify the target genes of miR‐34 in eyestalk. Six reproduction‐related genes with an intact 3′‐untranslated region (UTR), including molt‐inhibiting hormone (MIH), crustacean hyperglycemic hormone (CHH), vitellogenesis‐inhibiting hormone, red pigment concentrating hormone, ecdysone receptor (EcR), and farnesoic acid methyltransferase (FAMeT) were identified. When the 3′‐UTR plasmid vectors of the six genes were cotransfected with miR‐34 mimics into 293FT cells, respectively, the luciferase activities of four genes (MIH, CHH, EcR, and FAMeT) were significantly decreased compared with that in the control group; on the contrary, when the six plasmid vectors were cotransfected with the miR‐34 inhibitor respectively, the luciferase activities of four genes (MIH, CHH, EcR, and FAMeT) were significantly higher than that in the control group. When agomiR‐34 and antagomiR‐34 were injected into the eyestalk respectively in vivo, the expression levels of the MIH, CHH, EcR, and FAMeT genes were detected by a quantitative real‐time polymerase chain reaction. The results showed that agomiR‐34 suppressed the expression of the four genes, whereas antagomiR‐34 enhanced their expression. These experimental results confirmed our hypothesis that miR‐34 may indirectly regulate reproduction via binding to the 3′‐UTRs of MIH, CHH, EcR, and FAMeT genes and suppressing their expression.     

Functional Assessment of Residues in the Amino- and Carboxyl-Termini of Crustacean Hyperglycemic Hormone (CHH) in the Mud Crab Scylla olivacea Using Point-Mutated Peptides

To assess functional importance of the residues in the amino- and carboxyl-termini of crustacean hyperglycemic hormone in the mud crab Scylla olivacea (Sco-CHH), both wild-type and point-mutated CHH peptides were produced with an amidated C-terminal end. Spectral analyses of circular dichroism, chromatographic retention time, and mass spectrometric analysis of the recombinant peptides indicate that they were close in conformation to native CHH and were produced with the intended substitutions. The recombinant peptides were subsequently used for an in vivo hyperglycemic assay. Two mutants (R13A and I69A rSco-CHH) completely lacked hyperglycemic activity, with temporal profiles similar to that of vehicle control. Temporal profiles of hyperglycemic responses elicited by 4 mutants (I2A, F3A, D12A, and D60A Sco-CHH) were different from that elicited by wild-type Sco-CHH; I2A was unique in that it exhibited significantly higher hyperglycemic activity, whereas the remaining 3 mutants showed lower activity. Four mutants (D4A, Q51A, E54A, and V72A rSco-CHH) elicited hyperglycemic responses with temporal profiles similar to those evoked by wild-type Sco-CHH. In contrast, the glycine-extended version of V72A rSco-CHH (V72A rSco-CHH-Gly) completely lost hyperglycemic activity. By comparing our study with previous ones of ion-transport peptide (ITP) and molt-inhibiting hormone (MIH) using deleted or point-mutated mutants, detail discussion is made regarding functionally important residues that are shared by both CHH and ITP (members of Group I of the CHH family), and those that discriminate CHH from ITP, and Group-I from Group-II peptides. Conclusions summarized in the present study provide insights into understanding of how functional diversification occurred within a peptide family of multifunctional members.     

Inhibiting and stimulating neuropeptides controlling reproduction in Crustacea

Summary

Studies on the control of reproduction in crustaceans have, for the most part, dealt with the regulation of female reproduction. However, not a great deal of attention has been paid to cellular interactions of the neurohormones involved in this regulation. In this contribution recent data on inhibitory and stimulatory neuropeptides are discussed and reflections are made on their importance for further application-directed research. Attention is paid to: histophysiological events in the oocytes during vitellogenesis; biochemical aspects of the regulating neuropeptides and cytological localization of these neuropeptides in the neuroendocrine system. Opportunities for further research are identified and appraised in light of the knowledge reviewed.     

GABA and GAD expression in the X-organ sinus gland system of the <Emphasis Type="Italic">Procambarus clarkii</Emphasis> crayfish: inhibition mediated by GABA between X-organ neurons

In crustaceans, the X-organ-sinus gland (XO-SG) neurosecretory system is formed of distinct populations of neurons that produce two families of neuropeptides: crustacean hyperglycemic hormone and adipokinetic hormone/red pigment-concentrating hormone. On the basis of electrophysiological evidence, it has been proposed that γ-aminobutyric acid (GABA) regulates both electrical and secretory activity of the XO-SG system. In this work we observed that depolarizing current pulses to neurons located in the external rim of the X-organ induced repetitive firing that suppressed the spontaneous firing of previously active X-organ neurons. Picrotoxin reversibly blocked this inhibitory effect suggesting that the GABA released from the stimulated neuron inhibited neighboring cells. Immunoperoxidase in X-organ serial sections showed co-localization of GABA and glutamic acid decarboxylase (GAD) including the aforementioned neurons. Immunofluorescence in whole mount preparations showed that two subpopulations of crustacean hyperglycemic hormone-containing neurons colocalized with GABA. The expression of GAD mRNA was determined in crayfish tissue and X-organ single cells by RT-PCR. Bioinformatics analysis shows, within the amplified region, 90.4% consensus and 41.9% identity at the amino acid level compared with Drosophila melanogaster and Caenorhabditis elegans. We suggest that crustacean hyperglycemic hormone-GABA-containing neurons can regulate the excitability of other X-organ neurons that produce different neurohormones.     

Expression of recombinant eyestalk crustacean hyperglycemic hormone from the tropical land crab, <Emphasis Type="Italic">Gecarcinus lateralis</Emphasis>, that inhibits Y-organ ecdysteroidogenesis in vitro

Crustacean hyperglycemic hormone (CHH) is a pleiotropic neuropeptide that regulates carbohydrate and lipid metabolism, molting, reproduction, and osmoregulation in decapod crustaceans. CHH elevates glucose levels in the hemolymph by stimulating glycogenolysis in target tissues. It also inhibits ecdysteroidogenesis in the molting gland, or Y-organ (YO), possibly as a response to environmental stress. CHH acts via binding to a membrane receptor guanylyl cyclase, which is expressed in most tissues, including the YO. Large amounts of biologically active neuropeptide are required to investigate the mechanism of CHH signaling in the YO. Consequently, the eyestalk ganglia CHH (EG-CHH) isoform was cloned into a yeast (Pichia pastoris) expression vector to express recombinant mature peptide (rEG-CHH) with or without a C-terminal c-Myc/polyhistidine tag. Yeast cultures with untagged or tagged rEG-CHH inhibited ecdysteroidogenesis in YOs from European green crab (Carcinus maenas) 36% (P < 0.002) and 51% (P < 0.006), respectively. Purified tagged EG-CHH inhibited YO ecdysteroidogenesis 32% (P < 0.002), but lacked hyperglycemic activity in vivo. This is the first report of recombinant EG-CHH inhibiting YO ecdysteroidogenesis. The data suggest that the tagged recombinant peptide can be used to elucidate the CHH signaling pathway in the crustacean molting gland.     

Hormonal Control of Sexual Differentiation and Reproduction in Crustacea

SYNOPSIS. Sexual differentiation in malacostracan Crustaceais controlled by the androgenic gland hormone (AGH). In males,the primordial androgenic glands (AG) develop and AGH inducesmale morphogenesis. In females, the primordial AG does not developand the ovaries differentiate spontaneously. Implantation ofthe AG into females yields various results, showing that thesensitivity to AGH differs with the species and the receptiveorgans. Purified AGH of the isopod Armadillidium vulgare consistsof at least two molecular forms, which exist as monomeric proteinswith molecular weights of 17,000 ± 800 and 18,300 ±1,000 Da and with isoelectric points of about 4.5 and 4.3, respectively.The antiserum raised against purified AGH makes it possibleto measure AGH activity by immunoassay. Neurohormones control male and female reproduction. In males,they are involved in the maintenance of the male germinativezone and the control of AG activity. In females, the secondaryvitellogenesis is controlled by the vitellogenesis-inhibitinghormone (VIH) and the vitellogenesis- stimulating hormone (VSH).VIH isolated from the lobster Homarus americanus is a peptidewith a molecular weight of 9,135 Da and shows homology to thecrustacean hyperglycemic hormone and moltinhibiting hormone.Involvement of the molting hormone and the juvenile hormone-likecompound in the secondary vitellogenesis have also been suggested.In the amphipod Orchestia gammarella, the vitellogenesis- stimulatingovarian hormone (VSOH) seems to control vitellogenin synthesis     

A comparative immunocytochemical investigation of the crustacean hyperglycemic hormone (CHH) in the eyestalks of some decapod crustacea

The eyestalk of the astacideans Orconects limosus, Nephrops norvegicus, and Homarus gammarus, and the palinuran Palinurus vulgaris, was examined with an antiserum raised against purified crustacean hyperglycemic hormone (CHH) of the astacidean species Astacus leptodactylus. A distinct immunopositive reaction occurs in a group of neurosecretory cells in the medulla terminalis ganglionic X-organ (MTGX), in the MTGX-sinus gland tractus, and in a considerable part of the sinus gland. The immunoreactive sites in the eyestalk of the investigated species correspond to the site of production, storage, and release of the CHH. Preliminary investigations with this antiserum also indicate that a positive immunoreaction can be obtained in the eyestalk of other decapod crustaceans, for example, of the brachyuran Macropipus puber and the caridean Palaemon serratus.     

Sterols and steroids in a freshwater crustacean (Proasellus meridianus): hormonal response to nutritional input

For crustaceans that eat shredded plant material in freshwater habitats, the amount and the composition of food greatly vary over time because of the seasonal succession of plant fragments and algal biomass. The acquisition of elements necessary for growth, immune defense, and reproduction depends largely on this variation in food type and availability. In particular, sterols that are required as cellular membrane components and as precursors of ecdysteroids (molting hormones) must be acquired through food because crustaceans do not synthesize the steroid nucleus de novo. The present study examined the possible link between nutrition, sterols, and ecdysteroids in an isopod, Proasellus meridianus. In a first step, quantitative and qualitative analyses of sterols of P. meridianus were performed by gas‐chromatography/mass spectrometry. The results suggested that members of P. meridianus are able to convert dietary plant sterols into cholesterol required for growth and reproduction. In a second step, by manipulating food availability and using an enzyme immuno‐assay, we showed that ecdysteroid content in males and females (ovigerous or not) of P. meridianus decreased significantly after a starvation period. A nutritional input following this starvation period triggered an increase in the ecdysteroid contents of these animals. The comparable ecdysteroid responses to food pulses in males and females suggested that a nutritional control on steroid hormones regulated growth or gametogenesis rather than egg maturation. Thus, it appears that P. meridianus possesses an efficient stop‐and‐go endocrine system that may have been selectively favored in response to seasonal pulses of food.     

Redescription of Paralagenophrys singularis (Kellicott) n. comb. (Ciliophora: Peritricha: Lagenophryidae)1

Lagenophrys singularis is removed from Lagenophrys and designated the type species of Paralagenophrys n. g. Compared to members of Lagenophrys, the oral area of P. singularis is radically distorted. Paralagenophrys apparently also lacks second-type division, a special phase of sexual reproduction characteristic of Lagenophrys and associated with its adaptation to symbiotic life on crustaceans. Members of Lagenophrys are obligate ectocommensals of crustaceans. In contrast, P. singularis (Kellicott, 1887) n. comb. occurs most often on the leaves of aquatic vascular plants.     

甲壳动物高血糖激素家族生理功能研究进展

甲壳动物高血糖激素家族是甲壳动物特有的神经多肽激素家族,主要由眼柄的X-器窦腺复合体(XO-SG)合成与分泌,包括高血糖激素(CHH)、蜕皮抑制激素(MIH)、性腺抑制激素(GIH)和大颚器抑制激素(MOIH),协同调控着甲壳动物的生长、繁殖与蜕皮等生理生化过程.本文就目前CHH家族神经肽的功能研究,包括功能研究的方法、各个激素的功能以及分泌调控等研究进展作一综述.     

Comparative distribution of a putative egg-laying hormone in neural and reproductive tissues of four Decapoda crustaceans

Evidence for the presence of a putative egg-laying (ELH) hormone has been previously described in the black tiger shrimp, Penaeus monodon, so a further investigation was carried out to detect its presence in a range of Decapoda crustaceans prior to a full molecular analysis. The crustaceans were represented by the Australian fresh water yabbie, Cherax destructor, the Australian southern rock lobster, Jasus edwardsii, the snow crab, Chionoecetes opilio, and the blue swimmer crab, Portunus pelagicus. Female cerebral ganglia, ventral nerve cords and gonads were investigated in a comparative study of the distribution of the immunoreactive hormone using immunoenzyme and immunofluorescence techniques. Immunoreactivity was detected in all tissues of interest, and the distribution patterns showed similarity within the four species, as well as that of P. monodon reported in the earlier study. There were minor variations. These data indicate that a putative ELH-like neuropeptide is widespread in crustaceans, and supports its previous identification in a range of molluscs and other invertebrates. Elucidation of the molecular structure of the peptide hormone and its encoding gene, as well as its involvement in spawning behaviour of crustaceans, is now fully under investigation.     

Isolation of a cDNA encoding a CHH-family peptide from the silkworm Bombyx mori

The crustacean hyperglycemic hormone (CHH) peptide family includes four types of neuropeptide in decapod and isopod crustaceans, and the ion-transport peptide in orthopteran insects. To identify a new member of this family in Insecta, a PCR-based search for cDNAs encoding CHH-family peptides was carried out in the silkworm Bombyx mori. A cDNA, named BmCHHL (Bombyx mori CHH-like protein), with an open reading frame of 110 amino acids was isolated. Sequence analyses suggested that the conceptual protein was a precursor of a peptide of 72 amino acids which was amidated at the carboxy terminus. The BmCHHL sequence exhibited significant similarities to members of the CHH family including the orthopteran ion-transport peptide. BmCHHL expression was detected in five or six cells (per hemisphere) in the frontal area of the brain in day 4 fifth instar larvae.     

芥菜WOX基因家族的全基因组鉴定与分析

WUSCHEL相关-同源盒(WUSCHEL related-homeobox, WOX)基因家族是一类植物特有的转录因子基因家族,在植物的生长发育过程中发挥重要作用。本研究利用芥菜(Brassica juncea)基因组数据,通过HUMMER、Smart等软件进行检索筛选,共鉴定出51个WOX基因家族成员。利用Expasy在线软件对这些家族成员的蛋白质分子量、氨基酸序列长度、等电点等进行分析,并利用生物信息学软件对芥菜WOX基因家族进化关系、保守区域、基因结构等进行系统性分析,将芥菜WOX基因家族分为古老支、中间支和WUS支/现代支3个亚家族。结构分析表明,同一亚家族内的WOX转录因子家族成员的保守结构域的种类、组织形式以及基因结构具有高度的一致性,而不同亚家族之间呈现一定的多样性。51个WOX基因不均匀分布于芥菜18条染色体上,这些基因的启动子大多含有响应光、激素和非生物逆境胁迫相关的顺式作用元件。利用转录组数据和实时荧光定量PCR (real-time fluorescence quantitative PCR, qRT-PCR)分析发现,芥菜WOX基因的表达具有时空特异性,其中B...     

Amino acid sequence of putative moult-inhibiting hormone from the crab Carcinus maenas.

Putative moult-inhibiting hormone (MIH) was isolated from sinus glands of the shore crab Carcinus maenas, and its primary structure determined by automated Edman degradation of endoproteinase derived peptide fragments. MIH is a 78 residue neuropeptide (deduced molecular mass 9181 Da) with three disulphide bridges and unblocked N- and C-termini. MIH shows some homology to the crustacean hyperglycemic hormone (CHH) neuropeptide family. However, consideration of the roles of various members of this group, together with sequence information recently reported, strongly suggests that these neuropeptides may be multifunctional.